Mercurial > gemma
view pkg/controllers/cross.go @ 5718:3d497077f888 uploadwg
Implemented direct file upload as alternative import method for WG.
For testing and data corrections it is useful to be able to import
waterway gauges data directly by uploading a xml file.
author | Sascha Wilde <wilde@sha-bang.de> |
---|---|
date | Thu, 18 Apr 2024 19:23:19 +0200 |
parents | 5f47eeea988d |
children |
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// This is Free Software under GNU Affero General Public License v >= 3.0 // without warranty, see README.md and license for details. // // SPDX-License-Identifier: AGPL-3.0-or-later // License-Filename: LICENSES/AGPL-3.0.txt // // Copyright (C) 2018 by via donau // – Österreichische Wasserstraßen-Gesellschaft mbH // Software engineering by Intevation GmbH // // Author(s): // * Sascha L. Teichmann <sascha.teichmann@intevation.de> package controllers import ( "context" "database/sql" "fmt" "net/http" "time" "gemma.intevation.de/gemma/pkg/log" "gemma.intevation.de/gemma/pkg/mesh" "gemma.intevation.de/gemma/pkg/models" mw "gemma.intevation.de/gemma/pkg/middleware" ) func reproject( ctx context.Context, rp *models.Reprojector, src models.GeoJSONLineCoordinates, ) (models.GeoJSONLineCoordinates, error) { dst := make(models.GeoJSONLineCoordinates, len(src)) for i, s := range src { var err error if dst[i].Lat, dst[i].Lon, err = rp.Reproject( ctx, s.Lat, s.Lon, ); err != nil { return nil, err } } return dst, nil } const projectBackSQL = ` SELECT ST_AsBinary( ST_Transform(ST_GeomFromWKB($2, $1::integer), 4326))` func projectBack( ctx context.Context, line mesh.MultiLineStringZ, epsg uint32, conn *sql.Conn, ) (models.GeoJSONMultiLineCoordinatesZ, error) { var mls models.GeoJSONMultiLineCoordinatesZ err := conn.QueryRowContext( ctx, projectBackSQL, epsg, line.AsWKB(), ).Scan(&mls) return mls, err } func crossSection(req *http.Request) (jr mw.JSONResult, err error) { csi := mw.JSONInput(req).(*models.CrossSectionInput) start := time.Now() ctx := req.Context() conn := mw.JSONConn(req) tree, err := mesh.FromCache( ctx, conn, csi.Properties.Bottleneck, csi.Properties.Date.Time) log.Infof("loading mesh took %s\n", time.Since(start)) if err != nil { return } if tree == nil { err = mw.JSONError{ Code: http.StatusNotFound, Message: fmt.Sprintf("Cannot find survey for %s/%s.", csi.Properties.Bottleneck, csi.Properties.Date.Time), } return } // The coordinate system of the mesh is an UTM projection. // The input coordinates are in WGS84. // So we need to reproject them. start = time.Now() var rp *models.Reprojector if rp, err = models.NewReprojector( ctx, conn, models.WGS84, tree.EPSG(), ); err != nil { return } defer rp.Close() coords, err := reproject(ctx, rp, csi.Geometry.Coordinates) log.Infof("transforming input coords took %s\n", time.Since(start)) if err != nil { return } start = time.Now() var segments mesh.MultiLineStringZ for i := 0; i < len(coords)-1; i++ { c1 := &coords[i] c2 := &coords[i+1] verticalLine := mesh.NewVerticalLine(c1.Lat, c1.Lon, c2.Lat, c2.Lon) var line mesh.MultiLineStringZ tree.Vertical(c1.Lat, c1.Lon, c2.Lat, c2.Lon, func(t *mesh.Triangle) { if ls := verticalLine.Intersection(t); len(ls) > 0 { line = append(line, ls) } }) if len(line) > 0 { log.Infof("line length: %d\n", len(line)) // They are all on the segment (c1.Lat, c1.Lon) - (c2.Lat, c2.Lon). // Sort them by project them on this line. joined := line.JoinOnLine(c1.Lat, c1.Lon, c2.Lat, c2.Lon) log.Infof("joined length: %d\n", len(joined)) segments = append(segments, joined...) } } log.Infof("mesh traversal took %s\n", time.Since(start)) start = time.Now() var joined models.GeoJSONMultiLineCoordinatesZ joined, err = projectBack( ctx, segments, tree.EPSG(), conn, ) log.Infof("projecting back took %s\n", time.Since(start)) if err != nil { return } jr = mw.JSONResult{ Result: &models.CrossSectionOutput{ Type: "Feature", Geometry: models.CrossSectionOutputGeometry{ Type: "MultiLineString", Coordinates: joined, }, }, } return }